Laser cooling of a Planck mass object close to the quantum ground state

Laser cooling of a Planck mass object close to the quantum ground state

Quantum mechanics has so far not been tested for mechanical objects at the scale of the Planck mass $\sqrt{\hbar c/ G} \simeq 22\,\mu\mathrm{g}$. We present an experiment where a 1 mm quartz micropillar resonating at 3.6 MHz with an effective mass of 30 $\mu$g is cooled to 500 mK with a dilution ref...

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Hauptverfasser: Neuhaus, Leonhard, Metzdorff, Remi, Zerkani, Salim, Chua, Sheon, Teissier, Jean, Garcia-Sanchez, Daniel, Deleglise, Samuel, Jacqmin, Thibaut, Briant, Tristan, Degallaix, Jerome, Dolique, Vincent, Cagnoli, Geppo, Traon, Olivier Le, Chartier, Claude, Heidmann, Antoine, Cohadon, Pierre-Francois
Format: Artikel
Sprache:eng
Schlagworte:
Physics - Quantum Physics
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Zusammenfassung:Quantum mechanics has so far not been tested for mechanical objects at the scale of the Planck mass $\sqrt{\hbar c/ G} \simeq 22\,\mu\mathrm{g}$. We present an experiment where a 1 mm quartz micropillar resonating at 3.6 MHz with an effective mass of 30 $\mu$g is cooled to 500 mK with a dilution refrigerator, and further optomechanically sideband-cooled to an effective temperature of 3 mK, corresponding to a mode thermal occupancy of 20 phonons. This nearly 1000-fold increase in the mass of an optomechanical system with respect to previous experiments near the quantum ground state opens new perspectives in the exploration of the quantum/classical border.
DOI:10.48550/arxiv.2104.11648